solar cell materials

November 11, 2013

New perovskite oxide materials enable both efficient absorption and extraction of electronic carriers.

For solar panels, wringing every drop of energy from as many photons as possible is imperative. This goal has sent chemistry, materials science and electronic engineering researchers on a quest to boost the energy-absorption efficiency of photovoltaic devices, but existing techniques are now running up against limits set by the laws of physics.

Now, researchers from Drexel University and the University of Pennsylvania have experimentally demonstrated a new paradigm for solar cell construction which may ultimately make them less expensive, easier to manufacture and more efficient at harvesting energy from the sun.

The study was led by Jonathan E. Spanier, PhD, a professor in the College of Engineering at Drexel; Andrew M. Rappe, PhD, and research specialist Ilya Grinberg of the Department of Chemistry in Penn’s School of Arts and Sciences; and Peter K. Davies, PhD, chair of the Department of Materials Science and Engineering in the School of Engineering and Applied Science at Penn.

Existing solar cells all work in the same fundamental way: they absorb light, which excites electrons and causes them to flow in a certain direction. This flow of electrons is electric current. But to establish a consistent direction of their movement, or polarity, solar cells need to be made of two materials. Once an excited electron crosses over the interface from the material that absorbs the light to the material that will conduct the current, it can’t cross back, giving it a direction.

“There’s a small category of materials, however, that when you shine light on them, the electron takes off in one particular direction without having to cross from one material to another,” Rappe said. “We call this the ‘bulk’ photovoltaic effect, rather than the ‘interface’ effect that happens in existing solar cells. This phenomenon has been known since the 1970s, but we don’t make solar cells this way because they have only been demonstrated with ultraviolet light, and most of the energy from the sun is in the visible and infrared spectrum.”

Finding a material that exhibits the bulk photovoltaic effect for visible light would greatly simplify solar cell construction. Moreover, it would be a way around an inefficiency intrinsic to interfacial solar cells, known as the Shockley-Queisser limit, where some of the energy from photons is lost as electrons wait to make the jump from one material to the other.

“Think of photons coming from the sun as coins raining down on you, with the different frequencies of light being like pennies, nickels, dimes and so on,” Rappe said. “A quality of your light-absorbing material called its ‘bandgap’ determines the denominations you can catch. The Shockley-Queisser limit says that whatever you catch is only as valuable as the lowest denomination your bandgap allows. If you pick a material with a bandgap that can catch dimes, you can catch dimes, quarters and silver dollars, but they’ll all only be worth the energy equivalent of 10 cents when you catch them.

“If you set your limit too high, you might get more value per photon but catch fewer photons overall and come out worse than if you picked a lower denomination,” he said. “Setting your bandgap to catch only silver dollars is like only being able to catch UV light. Setting it to catch quarters is like moving down into the visible spectrum. Your yield is better even though you’re losing most of the energy from the UV you do get.”

As no known materials exhibited the bulk photovoltaic effect for visible light, the research team turned to its materials scientists to devise how a new one might be fashioned and its properties measured.

Starting more than five years ago, the team began theoretical work, plotting the properties of hypothetical new compounds that would have a mix of these traits. Each compound began with a “parent” material that would impart the final material with the polar aspect of the bulk photovoltaic effect. To the parent, a material that would lower the compound’s bandgap would be added in different percentages. These two materials would be ground into fine powders, mixed together and then heated in an oven until they reacted together. The resulting crystal would ideally have the structure of the parent but with elements from the second material in key locations, enabling it to absorb visible light.

“The design challenge,” Davies said, “was to identify materials that could retain their polar properties while simultaneously absorbing visible light. The theoretical calculations pointed to new families of materials where this often mutually exclusive combination of properties could in fact be stabilized.”

This structure is something known as a perovskite crystal. Most light absorbing materials have a symmetrical crystal structure, meaning their atoms are arranged in repeating patterns up, down, left, right, front and back. This quality makes those materials non-polar; all directions “look” the same from the perspective of an electron, so there is no overall direction for them to flow.

A perovskite crystal has the same cubic lattice of metal atoms, but inside of each cube is an octahedron of oxygen atoms, and inside each octahedron is another kind of metal atom. The relationship between these two metallic elements can make them move off center, giving directionality to the structure and making it polar.

“All of the good polar, or ferroelectric, materials have this crystal structure,” Rappe said. “It seems very complicated, but it happens all of the time in nature when you have a material with two metals and oxygen. It’s not something we had to architect ourselves.”

After several failed attempts to physically produce the specific perovskite crystals they had theorized, the researchers had success with a combination of potassium niobate, the parent, polar material and barium nickel niobate, which contributes to the final product’s bandgap.

The researchers used X-ray crystallography and Raman scattering spectroscopy to ensure they had produced the crystal structure and symmetry they intended. They also investigated its switchable polarity and bandgap, showing that they could indeed produce a bulk photovoltaic effect with visible light, opening the possibility of breaking the Shockley-Queisser limit.

Moreover, the ability to tune the final product’s bandgap via the percentage of barium nickel niobate adds another potential advantage over interfacial solar cells.

“The parent’s bandgap is in the UV range,” Spanier said, “but adding just 10 percent of the barium nickel niobate moves the bandgap into the visible range and close to the desired value for efficient solar energy conversion. So that’s a viable material to begin with, and the bandgap also proceeds to vary through the visible range as we add more, which is another very useful trait.”

Another way to get around the inefficiency imposed by the Shockley-Queisser limit in interfacial solar cells is to effectively stack several solar cells with different bandgaps on top of one another. These multi-junction solar cells have a top layer with a high bandgap, which catches the most valuable photons and lets the less valuable ones pass through. Successive layers have lower and lower bandgaps, getting the most energy out of each photon, but adding to the overall complexity and cost of the solar cell.

“The family of materials we’ve made with the bulk photovoltaic effect goes through the entire solar spectrum,” Rappe said. “So we could grow one material but gently change the composition as we’re growing, resulting in a single material that performs like a multi-junction solar cell.”

“This family of materials.” Spanier said, “is all the more remarkable because it is comprised of inexpensive, non-toxic and earth-abundant elements, unlike compound semiconductor materials currently used in efficient thin-film solar cell technology.”

The research was supported by the Energy Commercialization Institute of Ben Franklin Technology Partners, the Department of Energy’s Office of Basic Sciences, the Army Research Office, the American Society for Engineering Education, the Office of Naval Research and the National Science Foundation.

Gaoyang Gou of Chemistry; D. Vincent West, David Stein and Liyan Wu of Materials Science and Engineering at Penn; and Maria Torres, Andrew Akbashev, Guannan Chen and Eric Gallo of Drexel's Materials Science and Engineering Department, also contributed to the study.

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